Uniaxially-strained fd-soi finfet

ABSTRACT

Methods and structures for forming uniaxially-strained, nanoscale, semiconductor bars from a biaxially-strained semiconductor layer are described. A spatially-doubled mandrel process may be used to form a mask for patterning dense, narrow trenches through the biaxially-strained semiconductor layer. The resulting slicing of the biaxially-strained layer enhances carrier mobility and can increase device performance.

CROSS REFERENCE TO RELATED APPLICATION

The present application is a divisional of U.S. patent application Ser.No. 14/447,678, filed Jul. 31, 2014, which is incorporated herein byreference in its entirety.

BACKGROUND

1. Technical Field

The technology relates to methods and structures for increasing currentflow in strained semiconductor material.

2. Discussion of the Related Art

Transistors are fundamental device elements of modem digital processorsand memory devices, and have found numerous applications in variousareas of electronics including data processing, data storage, andhigh-power applications. Currently, there are a variety of transistortypes and designs that may be used for different applications. Varioustransistor types include, for example, bipolar junction transistors(BJT), junction field-effect transistors (JFET),metal-oxide-semiconductor field-effect transistors (MOSFET), verticalchannel or trench field-effect transistors, and superjunction ormulti-drain transistors.

Two types of transistors have emerged within the MOSFET family oftransistors that show promise for scaling to ultra-high density andnanometer-scale channel lengths. One of these transistor types is aso-called fin field-effect transistor or “finFET.”

The channel of a finFET is formed as a three-dimensional fin that mayextend from a surface of a substrate. FinFETs have favorableelectrostatic properties for complementary MOS (CMOS) scaling to smallersizes. Because the fin is a three-dimensional structure, thetransistor's channel can be formed on three surfaces of the fin, so thatthe finFET can exhibit a high current switching capability for a givensurface area occupied on substrate. Since the channel and device can beraised from the substrate surface, there can be reduced electric fieldcoupling between adjacent devices as compared to conventional planarMOSFETs.

The second type of transistor is called a fully-depleted,silicon-on-insulator or “FD-SOI” FET. The channel, source, and drain ofan FD-SOI FET is formed in a thin planar semiconductor layer thatoverlies a thin insulator. Because the semiconductor layer and theunderlying insulator are thin, the bulk region of the transistor (thatlies below the thin insulator and is sometimes referred to as a “backbody” region) can act as a second backside gate for the thin body in thethin semiconductor layer. The thin layer of semiconductor on insulatorpermits higher body biasing voltages that can either boost performanceor reduce leakage current depending on the desired operating mode. Thethin insulator also reduces leakage current to a transistor's bodyregion that would otherwise occur in bulk FET devices.

SUMMARY

The described technology relates to methods and structures for forminguniaxially-strained, nanoscale, semiconductor bars from abiaxially-strained layer of semiconductor. The methods and structuresmay be applied to the fabrication of FD-SOI transistors or any planartransistor in which the channel region is formed in a thin layer (e.g.,a layer having a thickness less than approximately 30 nm) of strainedsemiconductor material. By converting a biaxially-strained layer toclosely spaced, uniaxially-strained semiconductor bars, the current flowthrough the device may be increased by 30% or more. To form the closelyspaced, uniaxially-strained, nanoscale, semiconductor bars, aspatially-doubled mandrel process may be used.

According to some embodiments, a strained-channelsemiconductor-on-insulator transistor may comprise an insulating layerformed on a substrate, a plurality of nanoscale, strained semiconductorbars disposed on the insulator, and a gate formed over the plurality ofnanoscale, strained semiconductor bars, wherein a spacing between thebars is less than 30 nm. A strained-channel semiconductor-on-insulatortransistor may further comprise a channel region under the gate formedfrom a first portion of the plurality of nanoscale, strainedsemiconductor bars. In some implementations, a width of thesemiconductor bars is greater than the spacing between the bars. In someaspects, the spacing between the bars is less than 10 nm.

According to some implementations, the plurality of nanoscale, strainedsemiconductor bars may have a uniaxial strain ratio at the channelregions greater than 10:1. In some implementations, the plurality ofnanoscale, strained semiconductor bars may have a uniaxial strain ratioat the channel regions greater than 50:1. In some aspects, the channelregions may be fully depleted.

In some implementations, the insulating layer below the strainedsemiconductor bars is an ultra-thin buried oxide having a thickness lessthan 25 nm. In some aspects, the transistor is a FD-SOI transistorhaving an ultra-thin body, which is sliced into a plurality ofuniaxially-strained semiconductor bars, and buried oxide layer.

According to some aspects, a width of each bar of the plurality ofnanoscale, strained semiconductor bars is between approximately 10 nmand approximately 200 nm and a height of each bar is less thanapproximately 20 nm. In some aspects, the semiconductor bars are formedfrom silicon, whereas in other aspects, the semiconductor bars areformed from SiGe or SiC or any 111-V material.

According to some implementations, a strained-channelsemiconductor-on-insulator transistor may further comprise source and/ordrain merging material formed at a source and/or drain region, whereinthe source region comprises first portions of the plurality ofnanoscale, strained semiconductor bars and the source merging materialelectrically connects the first portions. Similarly the drain regioncomprises second portions of the plurality of nanoscale, strainedsemiconductor bars and a drain merging material electrically connectsthe second portions. In some aspects, the source and/or drain mergingmaterial comprises an epitaxially-grown semiconductor material grownfrom the respective first and/or second portions of the plurality ofnanoscale, strained semiconductor bars.

In some implementations, at least one strained-channelsemiconductor-on-insulator transistor may be formed in a memory circuit.In some implementations, at least one strained-channelsemiconductor-on-insulator transistor may be formed in a microprocessorcircuit.

The foregoing aspects and implementations of a strained-channelsemiconductor-on-insulator transistor may be present in any suitablecombination in an embodiment of a strained-channelsemiconductor-on-insulator transistor that comprises a plurality ofsliced, uniaxially-strained, semiconductor bars. Additionally, any ofthe following method embodiments may be used to fabricate any of thetransistor embodiments.

According to some embodiments, a method for making closely spaced,uniaxially-strained, nanoscale, semiconductor bars for FD-SOItransistors may comprise forming an array of mandrels adjacent abiaxial-strained semiconductor layer, wherein the strained semiconductorlayer is disposed on an insulating layer formed on a substrate, andconformally coating the mandrels with a spacer layer. The method mayfurther include acts of removing first portions of the spacer layer toexpose upper surfaces of the mandrels, and leaving second portions ofthe spacer layer adjacent to sidewalls of the mandrels. In someembodiments, the method further includes covering the mandrels andsecond portions with a first hard resist material, removing some of thefirst hard resist material to expose upper surfaces of the secondportions of the spacer layer, and removing the second portions of thespacer layer to form openings between the mandrels and remaining firsthard resist material. According to some embodiments, the method furthercomprises etching the pattern of the openings to the strainedsemiconductor layer to expose strips of the strained semiconductorlayer.

In some aspects, a method for making uniaxially-strained, nanoscale,semiconductor bars may comprise oxidizing the exposed strips to formuniaxially-strained, nanoscale, semiconductor bars. In some aspects, amethod for making uniaxially-strained, nanoscale, semiconductor bars maycomprise etching through the exposed strips to form nanoscale,semiconductor bars. According to some implementations, the exposedportions of the strained semiconductor layer have a width defined by athickness of the spacer layer that is less than approximately 30 nm. Insome implementations, the exposed portions of the strained semiconductorlayer have a width defined by a thickness of the spacer layer that isless than approximately 10 nm.

According to some implementations, etching the exposed portions of thestrained semiconductor layer converts biaxial strain in thesemiconductor layer to predominantly uniaxial strain. In some aspects, auniaxial strain ratio of semiconductor bars formed after etching thesemiconductor layer is greater than 10:1. In some aspects, a uniaxialstrain ratio of semiconductor bars formed after etching thesemiconductor layer is greater than 50:1.

According to some implementations, a method for makinguniaxially-strained, nanoscale, semiconductor bars may further compriseremoving the mandrels and first hard resist material, and forming a gatestructure over a plurality of the uniaxially-strained, nanoscale,semiconductor bars. In some implementations, forming the gate structurecomprises forming a gate insulator over at least a portion of theuniaxially-strained, nanoscale, semiconductor bars, and forming a gateconductor over the gate insulator.

In some aspects, a method for making uniaxially-strained, nanoscale,semiconductor bars may further comprise forming a merging semiconductormaterial at source and/or drain regions of the uniaxially-strained,nanoscale, semiconductor bars to electrically connect theuniaxially-strained, nanoscale, semiconductor bars at the source and/ordrain regions. In some implementations, a method further comprisesepitaxially growing a semiconductor material at source and/or drainregions of the uniaxially-strained, nanoscale, semiconductor bars toelectrically connect the uniaxially-strained, nanoscale, semiconductorbars at the source and/or drain regions.

According to some implementations, a method for makinguniaxially-strained, nanoscale, semiconductor bars may further compriseetching through a second hard mask located between the mandrels andstrained semiconductor layer. In some aspects, a method may furthercomprise etching through exposed portions of the insulating layer afteretching the exposed portions of the strained semiconductor layer. Insome implementations, a method may further include filling regionsbetween the uniaxially-strained, nanoscale, semiconductor bars with aninsulator.

The foregoing aspects and implementations of acts to fabricateuniaxially-strained, nanoscale, semiconductor bars may be used in anysuitable combination for an embodiment of a method for makinguniaxially-strained, nanoscale, semiconductor bars and integratedelectronic devices that incorporate such bars.

The foregoing and other aspects, embodiments, and features of thepresent teachings can be more fully understood from the followingdescription in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The skilled artisan will understand that the figures, described herein,are for illustration purposes only. It is to be understood that in someinstances various aspects of the embodiments may be shown exaggerated orenlarged to facilitate an understanding of the embodiments. In thedrawings, like reference characters generally refer to like features,functionally similar and/or structurally similar elements throughout thevarious figures. The drawings are not necessarily to scale, emphasisinstead being placed upon illustrating the principles of the teachings.Where the drawings relate to microfabrication of integrated devices,only one device may be shown of a large plurality of devices that may befabricated in parallel. The drawings are not intended to limit the scopeof the present teachings in any way.

FIGS. 1A-1B depict a FD-SOI transistor and channel region, according tosome embodiments;

FIGS. 2A-2B depict a finFET and channel region, according to variousembodiments;

FIGS. 3A-3C depict strained semiconductor-on-insulator structures,according to some embodiments;

FIG. 4 depicts a plan view of uniaxially-strained, nanoscalesemiconductor bars, according to some embodiments;

FIGS. 5A-5J depict structures associated with methods for forminguniaxially-strained, nanoscale semiconductor bars, according to someimplementations;

FIGS. 5K-5M depict structures associated with methods for formingsemiconductor-on-insulating transistors from the uniaxially-strained,nanoscale semiconductor bars, according to some implementations;

FIGS. 6A-6B illustrate merged source and drain regions of a transistor,according to some embodiments;

FIGS. 7A-7D illustrate a dependence of transverse channel strain ondevice design variations, according to some embodiments;

FIG. 8 illustrates a dependence of transverse channel strain on devicedesign variations, according to some embodiments;

FIG. 9 illustrates experimentally-measured increases in current densitywith decreasing widths of a single channel that is initially strainedbiaxially;

FIGS. 10A and 10B represent numerical simulations of current gain fortwo approaches to forming uniaxially-strained, nanoscale semiconductorbars for different initial transistor dimensions; and

FIGS. 11A-11B illustrate enhancement of carrier mobility for twospacings between strained nanoscale bars as a function of bar width, insome embodiments.

The features and advantages of the embodiments will become more apparentfrom the detailed description set forth below when taken in conjunctionwith the drawings.

DETAILED DESCRIPTION

An example of a fully-depleted silicon-on-insulator (FD-SOI) FET 100 isdepicted in FIGS. 1A-1B, according to some embodiments. The FD-SOI FETmay comprise a source region 120, a gate structure 130, 135, 137, adrain region 140, and a channel region 150. The source, channel region,and drain may be farmed in a thin semiconductor layer 112 that is formedadjacent a thin insulating layer 105 or buried oxide layer 105. The thininsulating layer may be formed adjacent a substrate 110. In someembodiments, trench isolation structures 170 comprisingelectrically-insulating material may be formed around one or more FD-SOIFETs. The gate structure may comprise a gate conductor 130, spacers 137,and a thin gate insulator 135. According to some embodiments, integratedsource S, gate G, drain D, and body B interconnects may be formed toprovide electrical connections to the source, gate, drain, and back bodyregions of the FD-SOI FET.

In some embodiments, the source region 120 and drain region 140 of aFD-SOI FET may be doped with donor or acceptor impurities to formregions of a first conductivity type (e.g., n-type or p-type). Accordingto some implementations, the channel region 150 may comprise a single,continuous region of the semiconductor layer 112 and have a width W asdepicted in the drawings. The channel region 150 may be doped to be ofan opposite conductivity type than that of the source and drain regions.In some implementations, the channel region 150 may be undoped. In someembodiments, the channel region may be of a same conductivity type as aback body region 115.

An example of a finFET 200 is depicted in illustrations of FIGS. 2A-2B.A finFET may be fabricated on a bulk semiconductor substrate 110, e.g.,a silicon substrate, and comprise a fin-like structure 215 that runs ina length direction along a surface of the substrate and extends in aheight direction normal to the substrate surface. The fin 215 may have anarrow width, e.g., less than 50 nanometers. There may be anelectrically-insulating layer 205, e.g., an oxide layer having athickness up to 750 nm, on a surface of the substrate 110. In someimplementations, the insulating layer 205 may be thin, e.g., less than100 nm, and the fin may pass through the insulating layer 205, but beattached to the semiconducting substrate 110 at a lower region of thefin. A gate structure comprising a conductive gate material 230 (e.g.,polysilicon) and a gate insulator 235 (e.g., an oxide) may be formedover a region of the fin. A channel region 250 may be surrounded by thegate on three sides, and there may be a body region 255 near the base ofthe fin and/or centrally within the fin. The finFET may further includea source region 220 and drain region 240 adjacent to the gate. A finFETmay also include integrated source S, gate G, drain D, and body B (notshown) interconnects to provide electrical connections to the source,gate, drain, and back body regions of the device.

As explained above, FD-SOI FETs and finFETs can exhibit favorableelectrical characteristics when scaled to smaller sizes. FD-SOI FETs canhave some attractive features that are not realizable with finFETs. Forexample, independent back-body biasing is possible with FD-SOI devicesto control dynamically device threshold voltages. Also, FD-SOI can useconventional processing techniques for planar transistors, whereasfinFETs require more specialized fabrication techniques for formingout-of-plane source, channel, and drain regions. In some cases, it maybe easier to strain channel regions in FD-SOI devices than in finFETs.

The inventors have appreciated that several techniques may be used toform biaxially-strained semiconductor-on-insulator layers 320, asdepicted in FIGS. 3A-3C. According to some embodiments, a strainedsemiconductor-on-insulator (SSOI) layer may be formed using acts of ionimplantation, amorphization, and recrystallization, as described in U.S.patent application Ser. No. 14/253,904 titled, “Method to Co-integrateOppositely Strained Semiconductor Devices on a Same Substrate” and filedApr. 16, 2014, which is incorporated herein by reference in itsentirety. In some embodiments, an SSOI layer may be formed using actsfor forming a strain-inducing layer 380 on a substrate, forming asemiconductor layer adjacent the strain-inducing layer, and formingstress-relief isolation trenches 373 through the semiconductor layer 320and at least partially through the strain-inducing layer 380, asdescribed in U.S. patent application Ser. No. 14/186,342 titled, “Methodto Form Strained Channel in Thin BOX SOI Structures by Elastic StrainRelaxation of the Substrate” and filed Feb. 21, 2014, which isincorporated herein by reference in its entirety. Other techniques forforming a biaxially-strained, semiconductor-on-insulator layer may beused in other embodiments.

In some implementations, biaxially-strained, semiconductor-on-insulatorregions 312 may be formed between isolation trenches 373, as depicted inFIG. 3C using any suitable technique. The strained regions 312 may eachbe used to fabricate a FD-SOI transistor, having a channel width W andan active length S_(a). For example, an FD-SOI transistor as depicted inFIGS. 1A-1B may be formed at each region 312. Because of the strainpresent in the semiconductor layer 320, carrier mobility can be improvedcompared to a device having no strain in the semiconductor layer.

The inventors have conceived of techniques and structures for convertinga biaxially-strained semiconductor-on-insulator layer 320 into aplurality of nanoscale, uniaxially-strained semiconductor bars 390, asdepicted in FIG. 4. The inventors have appreciated that, in some cases,the conversion to uniaxial strain can yield higher carrier mobility thanbiaxial strain in the channel region. The inventors have found that insome cases, further improvements in device performance can be achievedby effectively slicing a biaxially-strained region 312 of width W into aplurality semiconductor bars 390 having widths W* that are appreciablysmaller than the initial channel width W of the device. The inventorshave found that the slicing (and resulting carrier mobility enhancement)can increase the amount of current switched by the device, even thoughthe cutting removes some semiconductor material from the channel regionthat would otherwise be available to carry current in the device. Deviceperformance can be improved through enhanced mobility attributed toconversion of biaxial strain to uniaxial strain in the semiconductor.

FIGS. 5A-5J depict structures associated with methods for forminguniaxially-strained, nanoscale semiconductor bars 390 frombiaxially-strained regions 312, according to some embodiments. Referringto FIG. 5A, a process for forming uniaxially-strained, nanoscalesemiconductor bars may begin with obtaining or forming abiaxially-strained semiconductor layer 112 on an insulator layer 105 ona substrate 110. The substrate 110 may be any suitable semiconductingsubstrate, or in some embodiments a ceramic or glass substrate. Forexample, substrate 110 may comprise bulk silicon, and may be in the formof a chip, die, or wafer. Substrate 110 may be formed from othersemiconducting materials in some implementations including, but notlimited to, group IV semiconductors and III-V semiconductors. Forexample, substrate 110 may be formed of any of the following materialsin some embodiments: Ge, SiGe, SiC, GaAs, InP, InGaAs, GaN, and AlGaAs.

In some embodiments, insulating layer 105 comprises an oxide, e.g., asilicon oxide, though in some implementations any other suitableinsulator may be used. The insulating layer 105 may have a thicknessbetween approximately 5 nm and approximately 30 nm, according to someembodiments. In some implementations, the insulating layer may have athickness between approximately 5 nm and approximately 15 nm. In someimplementations, the insulating layer 105 may be an insulating layer ofan ultra-thin body and buried oxide (UTBB) substrate. In otherembodiments, insulating layer 105 may comprise a nitride layer, or ahigh-K dielectric layer.

The terms approximately, “substantially,” and “about” may be used hereinto mean within ±20% of a target value in some embodiments, within ±10%of a target value in some embodiments, within ±5% of a target value insome embodiments, and yet within ±2% of a target value in someembodiments. The terms “approximately,” “substantially,” and “about” mayinclude the target value.

The biaxially-strained semiconductor layer 112 may be any suitablesemiconductor material. According to some embodiments, strainedsemiconductor layer comprises silicon (Si), or a compound semiconductorsuch as silicon germanium (SiGe) or silicon carbide (SiC). Othermaterials that may be used for strained semiconductor layer 112 include,but are not limited to: Ge, GaAs, InP, InGaAs, GaN, and AlGaAs. In someembodiments, the thickness of the strained semiconductor layer 112 isbetween approximately 3 nm and approximately 20 nm. In someimplementations, the thickness of the strained semiconductor layer isbetween approximately 5 nm and approximately 9 nm.

According to some embodiments, a first hard mask layer 510 may be formedover the strained semiconducting layer 112, as depicted in FIG. 5B. Asecond hard mask layer may be formed over the first hard mask layer 510,and patterned to form mandrels 520. The first and second hard masklayers may be formed by any suitable process, e.g., a vapor depositionprocess or physical deposition process. In some embodiments, aplasma-enhanced chemical-vapor deposition (PECVD) process or atomiclayer deposition (ALD) process may be used to form the first and secondhard mask layers.

The mandrels 520 may be formed by any suitable photolithography process.In some embodiments, the mandrels may be patterned as a gratingstructure having a periodicity of between approximately 80 nm andapproximately 1000 nm. In some implementations, the periodicity may belarger, for example, any value between 1 μm and 10 mm. The mandrels 520may be patterned by depositing and exposing a photoresist over thesecond hard mask layer, developing the photoresist, and etching throughthe second hard mask layer in regions where the photoresist has beenremoved to expose the second hard mask layer. The photoresist may besubsequently stripped from the wafer leaving the mandrels 520. In someembodiments, EUV lithography may be used in a process to patternmandrels 520. In some implementations, nanoimprint lithography may beused in a process to pattern the mandrels.

The first hard mask layer 510 and the mandrels 520 may be formed fromany suitable material or materials. In various embodiments, the firsthard mask layer 510 exhibits etch selectivity over the strainedsemiconductor layer 112. For example, the first hard mask layer 510 maybe etched with a dry or wet etching process that does not appreciablyetch the strained semiconductor layer 112. As a non-limiting example, ifthe strained semiconductor layer 112 is formed from silicon, the firsthard mask layer may be formed from silicon nitride (SiN_(x)) or an oxide(e.g., SiO_(x)).

According to some embodiments, the second hard mask layer (in which themandrels 520 will be formed) exhibits etch selectivity over the firsthard mask layer. Continuing with the above example, the second hard masklayer may be formed from silicon, whereas the first hard mask layer maybe formed of an oxide or a nitride. Other material combinations may beused in other embodiments.

The thickness of the first hard mask layer may be between approximately10 nm and approximately 60 nm, and the thickness of the second hard masklayer may be between approximately 20 nm and approximately 100 nm. Invarious embodiments, the thickness of an upper masking layer will besufficiently thick so as to be able to etch through an underlying layerwithout completely removing the upper layer. For example, the first hardmask layer 510 may be thick enough such that during an etch through theunderlying strained semiconductor layer 112, at least some of the firsthard mask layer 510 will remain to cover portions of the semiconductorlayer 112 that are not intended to be etched. If there is high etchselectivity between successive layers, an upper layer may not be thickerthan a lower layer.

In various embodiments, a conformal layer 530 may be formed over themandrels 520, as depicted in FIG. 5B. The conformal layer 530 mayexhibit etch selectivity over the mandrels 520 and the first hard masklayer 510. For example, according to some embodiments, the conformallayer 530 may be formed of a nitride (e.g., SiN_(x)), the mandrels 520may be formed of silicon (e.g., polysilicon), and the first hard masklayer 510 may be formed of an oxide (e.g., SiO_(x)). With such acombination of materials, a wet or dry etch process (e.g., a dry etchcomprising CH₃F) may be used to etch the conformal layer 530 withoutappreciably etching the mandrels 520 or first hard mask layer 510. Othermaterial combinations may be used in other embodiments. The thickness ofthe conformal layer may be between approximately 3 nm and approximately60 nm, in some implementations. According to some embodiments, thethickness of the conformal layer 530 is between 3 nm and approximately15 nm. The conformal layer may be deposited by any suitable process,including a plasma deposition process or an atomic layer depositionprocess.

According to some implementations, the conformal layer 530 may be etchedback, as depicted in FIG. 5C. The etch-back may comprise a dryanisotropic etch (e.g., a reactive ion etch), in some embodiments. Theanisotropic etch may be timed, so that an amount of materialapproximately equivalent to the thickness of the conformal layer 530 isremoved. As a result, sidewall spacers 532 will remain at sidewallportions of the mandrels 520 after the anisotropic etch, as depicted inFIG. 5C. The lateral widths of the sidewall spacers 532 will beapproximately equivalent to the thickness of the conformal layer 530 asdeposited.

In a subsequent step, as depicted in FIG. 5D, a filler hard mask 540 maybe formed over the substrate. The filler hard mask may be deposited byany suitable vapor or physical deposition process. According to someembodiments, the filler hard mask 540 may be formed of the same materialas the mandrels 520, though in other embodiments a different materialmay be used. The thickness of the filler hard mask 540 may be equivalentto, or greater than, the thickness of the mandrels, according to someembodiments. As illustrated, the filler hard mask may fill the regionsbetween the mandrels as well as cover the mandrels and the sidewallspacers 532.

In some implementations, at least a portion of the filler hard mask 540may be etched or removed, leaving a structure depicted in FIG. 5E. Forexample, a chemical mechanical polishing (CMP) process may be used toetch back the filler hard mask to the top of the sidewall spacers 532.The chemical mechanical polishing step may be selective to the fillerhard mask material, and not appreciably etch the sidewall spacermaterial 532. Accordingly, the CMP step may effectively stop on thesidewall spacer material. After the etch-back of the filler hard maskmaterial 540, fillers 550 remain between sidewall spacers 532 andbetween mandrels 520. According to some embodiments, the mandrels have afirst lateral width W₁*, and the fillers 550 have a second lateral widthW₂*. Although the two widths W₁* and W₂* are shown as beingsubstantially equal in FIG. 5E, in some embodiments, the widths may bedifferent.

It may be appreciated from the depictions in FIGS. 5A-5E that a spatialperiodicity of the mandrels is effectively reduced by a factor of twousing the spacer layer 530 and filler layer 540. As will be seen in thefollowing illustrations, the process substantially reduces the gapsbetween the original mandrels (see FIG. 5B) to a smaller dimensionsubstantially defined by the thickness of the spacer layer 530 (see FIG.5F). In some embodiments, the process described in FIGS. 5A-5E may berepeated. For example the sidewall spacers 532 or the mandrels 520 andfillers 550 may be removed from the structure shown in FIG. 5E, and asecond, thinner conformal layer (not shown) may be formed over themandrels 520 and fillers 550. The steps depicted in FIGS. 5C-5E may thenbe repeated.

According to some embodiments, the sidewall spacers 532 may be removedby a wet etch or a dry etch. In some implementations, a reactive ionetch (RIE) may be used to remove sidewall spacers. In someimplementations, a wet isotropic etch (e.g., a hot phosphoric etchcomprising H₃PO₄ acid) may be used to remove the sidewall spacers. Insome embodiments, a dry anisotropic etch may be used to remove sidewallspacers 532, and a same or different etch recipe may be used to removeexposed portions of the underlying first hard mask layer 510. The etchmay continue to the top of the strained semiconductor layer 112, in someembodiments, resulting in the structure depicted in FIG. 5F. The etchingto the top of the strained semiconductor layer 112 may expose stripsalong the top surface of the layer 112.

In some implementations, a dry anisotropic etch may be used to etchthrough the biaxially-strained semiconducting layer 112, as depicted inFIG. 5G. Etching through the biaxially-strained semiconductor layer 112effectively cuts or slices the strained semiconductor layer to yield thenanoscale semiconductor bars 390. Because of the cutting, strain that istransverse to the length of the bars is relieved, and the remainingstrain in the semiconductor bars 390 can be substantially uniaxial. Theresulting type of strain can be compressive or tensile along the lengthsof the bars. In various embodiments, the type of strain (compressive ortensile) will be unchanged from the initial. The directionality of thestrain (biaxial or uniaxial) can change appreciably because of thecutting. Transformation from biaxial strain to uniaxial strain canimprove carrier mobility within the bars 390, according to someembodiments.

Any remaining material from the mandrels 520, fillers 550, and/or firsthard mask layer 510 may be removed from the substrate using a dry etchand/or a wet etch process or combination of processes, according to someembodiments. The resulting structure after removal of the mandrels,fillers, and first hard mask layer may be that depicted in FIG. 5H,according to some embodiments. In some implementations, the underlyingoxide 105 may be etched through before removing at least the first hardmask layer. In some embodiments, the first hard mask layer 510 may beformed of an oxide, so that some or all of this layer is removed in asubsequent etch through the underlying oxide 105. The resultingstructure may then be that shown in FIG. 5I Etching through theunderlying oxide layer 105 can further relieve transverse strain in thesemiconductor bars 390, according to some embodiments. In someembodiments, the underlying oxide 105 may not be etched, so that thestructure remains as shown in FIG. 5H.

In some implementations, the regions between the semiconductor bars 390may be filled with an oxide, as depicted in FIG. 5J. These regions maybe filled by depositing any suitable oxide with a suitable depositionprocess. For example, a silicon oxide may be deposited using a plasmadeposition process, or an atomic layer deposition process. In someembodiments, a shallow trench isolation process may be used to fill theregions between the semiconductor bars 390. In some implementations, theregions may be filled using an ethylene glycol (EG) oxide depositionprocess. After the regions are filled, the oxide may be etched back toexpose the top surfaces of the uniaxially-strained semiconductor bars390, e.g., using a CMP step. In other embodiments, the regions betweenthe semiconductor bars 390 may not be filled, leaving a structure likethat shown in FIG. 5H.

As an alternative process to producing a structure like that shown inFIG. 5J, in some implementations, etching of the mandrel and fillerpattern through the first hard mask layer 510 may be terminated at thebiaxially-strained semiconducting layer 112, as depicted in FIG. 5F.With at least the patterned first hard mask layer 510 remaining on thestrained semiconducting layer 112, the exposed portions of the strainedsemiconducting layer 112 may be oxidized. For example, the exposedportions may be subjected to a thermal oxidation process to convert theexposed portions into silicon dioxide. The conversion of those portionsto an oxide may provide the structure as shown in FIG. 5J. Subsequently,any remaining material from the mandrels, fillers, and/or first hardmask layer may be removed from the substrate.

In some embodiments, the conversion of portions of thebiaxially-strained semiconducting layer 112 to an oxide may also relievetransverse strain in the formed semiconductor bars. For example, if thebiaxially-strained layer 112 is under tensile stress, formation of thethermal oxide can form compressive stress locally. The compressivestress may cancel the transverse tensile stress, in some embodiments. Insome implementations, the conversion of portions of thebiaxially-strained semiconducting layer 112 to an oxide may increasestress along the length of the formed semiconductor bars 390. Forexample, compressive stress resulting from thermal oxidation in theregions between the bars may add more compressive stress along thelength of the bars than transverse to the bars. In some embodiments, theelastic modulus of the formed oxide may be appreciably lower than thatof the semiconductor bars, and allow for relaxation of the transversestress in the bars without significantly altering the longitudinalstress in the bars 390.

In various embodiments, a gate structure may be formed over theuniaxially-strained, nanoscale bars 390 that are depicted in either FIG.5H or FIG. 5J. For example, and referring to FIG. 5K, a gate insulator565 and gate conductor 570 may be formed over the semiconductor bars 390that have been formed according to the process described in connectionwith FIG. 5H. The gate insulator 565 may be formed by a thermaloxidation process, or it may be formed by a vapor deposition process(e.g., atomic layer deposition). In some implementations, the gateinsulator may be formed over a region of the substrate in whichsemiconductor bars 390 are located, or over a larger area. Subsequently,a gate conductor 570 may be patterned over the gate insulator. In someembodiments, a gate conducting material (e.g., polysilicon or a metalsilicide) may be deposited substantially uniformly over the region ofthe substrate. Photolithography (or any suitable lithographic process)may be used to pattern a resist over the gate conducting material. Thegate conducting material may then be etched, using the photoresist as anetch mask, to remove portions of the gate conducting material that willnot be used to form gate conductors 570. In some embodiments, a dryanisotropic etch may be used to etch the gate conducting material. Asubsequent etch may be carried out to remove exposed regions of gateinsulating material that is not under the remaining gate conductor 570,according to some embodiments.

According to some embodiments, a FD-SOI transistor may be formed from aplurality of uniaxially-strained, nanoscale bars 390, as depicted inFIG. 5L. FIG. 5L illustrates an embodiment in which a gate insulator 565is formed over a structure shown in FIG. 5J. In some embodiments, trenchisolation structures 580 may be formed around each transistor. Thetrench isolation structures 580 may comprise an oxide or any othersuitable insulator deposited in an etched trench. The trench isolationstructures may be patterned before the slicing of the strainedsemiconducting layer 112 or after the slicing of the strainedsemiconducting layer.

A plan view of one transistor comprising uniaxially-strainedsemiconductor bars 390 is illustrated in FIG. 5M, according to someembodiments. Because of the slicing of the biaxially-strainedsemiconductor layer, the resulting bars 390 have substantially uniaxialstrain. The device may have a length of its active area denoted S_(a),and the width of each bar may be W*. In some embodiments, alternatingbars may have different widths. There may be a plurality of nanoscalespaces 410 between each bar. The spaces 410 may be filled withinsulating material, in some embodiments. A width of the spaces may bebetween approximately 3 nm and 40 nm according to some embodiments, andbetween approximately 3 nm and 15 nm according to some implementations.

In some implementations, source and drain regions of the transistor 600may be merged, as depicted in FIGS. 6A-6B. For example, a mergingsemiconducting material 620 may be epitaxially grown or otherwise formedover the semiconductor bars 390 in each of the source and drain regions.The merging semiconductor 620 may grow from the bars and cross thesubstrate merging with epitaxially grown semiconducting material fromadjacent bars. In some cases, the bars may be merged using any suitablevapor or physical deposition process. A physical deposition process mayinclude, but not be limited to, sputtering or electron-beam evaporation.In some embodiments, the merging material may be a conductor (e.g., ametal or metal alloy) instead of a semiconductor. In variousembodiments, the merging material 620 provides a larger and moreconvenient region of contact for the source and drain regions of thetransistor 600, as may be appreciated by comparing FIG. 5M with FIGS.6A-6B.

According to some embodiments, the merging semiconducting material 620may be selected to further strain the channel regions of the device. Forexample, the merging semiconducting material 620 may have a latticeconstant that is mismatched from the underlying semiconductor bars 390.

In various embodiments, an FD-SOI transistor with a sliced active areamay comprise multiple nanoscale channels formed of semiconductor bars390. In some cases, as depicted in FIG. 5K, the multiple channels mayhave a three-dimensional structure underneath the gate conductor 570. Insuch an embodiment, the semiconductor bars may form inverted channels ontop and side surfaces of the semiconductor bars 390, similar to finFETdevices. Increased surface area for channel inversion can increase anamount of current that the device can carry, in addition to improvementsin current due to enhancements in carrier mobility by conversion touniaxial strain.

Because the semiconducting bars 390 are substantially uniaxiallystrained, the plurality of channel regions below the gate conductor (seeFIG. 1A, channel region 150) will also be uniaxially strained.Accordingly, enhancements in mobility are also realized in the channelregions. In some implementations, the uniaxially-strained channel regionmay be partially or fully depleted.

In some embodiments, the width or widths of the semiconductor bars 390may be between approximately 10 nm and approximately 1000 nm. In someembodiments, the width or widths of the semiconductor bars may bebetween approximately 10 nm and approximately 200 nm, and yet in someimplementations, the width or widths of the semiconductor bars may bebetween approximately 10 nm and approximately 100 nm. In someembodiments, the spaces 410 between the semiconductor bars 390 may bebetween approximately 3 nm and approximately 50 nm. The spaces betweenthe semiconductor bars may be between approximately 3 nm andapproximately 30 nm according to some embodiments, and yet betweenapproximately 3 nm and approximately 10 nm according to someembodiments. In some embodiments, the widths of the semiconducting bars390 is greater than the spaces 410 between the bars.

FIGS. 7A-7D depict structures and results from associated numericalsimulations of stress in SiGe semiconductor bars 390, according to someembodiments. FIG. 7A depicts a model of the semiconducting bar having awidth W*. The semiconducting bar sits on top of an oxide layer 105 thathas an approximately uniform thickness across the underlying substrate.FIG. 7C also depicts a model of a semiconducting bar of width W*.However, in the case of FIG. 7C, the underlying oxide layer has beenetched to remove portions that are not covered by the bar 390, asillustrated. The structure shown in FIG. 7A was selected for modelingpurposes to resemble the structure of FIG. 5H, and the structure shownin FIG. 7C was selected to resemble the structure shown in FIG. 5I.

FIG. 7B shows several traces of calculated stress in the semiconductingbar 390 as a function of the width W*of the bar. For the simulation, thebar is cut (etched) from a uniform, biaxially-strained layer ofsemiconducting material. For purposes of the model, the length of thebar is much greater than the width, so that end effects of the bar canbe ignored. The thickness of the semiconducting layer was taken to beapproximately 7 nm. The lower trace 730 in the graph represents valuesof transverse stress (in the direction of the bar's width) calculatedacross the bar when the bar has a width W* of approximately 1 μm. Theupper trace 710 represents values of transverse stress within the barwhen the bar width is approximately 40 nm. As may be appreciated fromthe traces, a substantial amount of the transverse stress can berelieved by cutting the bar to narrow widths. In the example,approximately 1/10^(th) of the transverse stress remains in a bar cut toa width of 40 nm, as compared to a bar cut to a width of approximately 1μm.

Stress relief is more pronounced for the case shown in FIG. 7C. FIG. 7Dillustrates the corresponding values of transverse stress for anembodiment in which the underlying oxide 105 is also etched. In FIG. 7D,the lower curve 730 represents the case where the width of thesemiconductor bar 390 is 1 μm, and the top curve 710 represents a casewhere the width of the semiconductor bar is 40 nm. For the intermediatetraces, the widths of the semiconductor bar was 800 nm, 500 nm, 300 nm,200 nm, 100 nm, and 80 nm._As can be seen in FIG. 7D, nearly all of thetransverse stress is relieved in the semiconductor bar cut to a width of20 nm. In the case of FIGS. 7C-7D, additional transverse stress reliefis obtained by etching the underlying oxide layer. For the simulationscorresponding to FIG. 7A-7D, a thickness of the semiconductor bar 390was taken to be approximately 6 nm, and a thickness of the underlyingoxide 105 was taken to be approximately 25 nm.

A uniaxial stress ratio may be estimated from the graphs of FIG. 7B andFIG. 7D, in some embodiments. For example, the biaxial stress for bothcases can be observed to be approximately −1.15 gigaPascals (GPa), asobserved at the center of the bar for the widest bars (lower traces730). By cutting the bar to a width W* of 20 nm for the embodimentdepicted in FIG. 7A, the transverse stress reduces to approximately −0.1GPa, whereas the stress along the length of the bar remainssubstantially the same (not shown in the graph). Accordingly, for theembodiment shown in FIG. 7A, the uniaxial stress ratio becomes at least10:1 when the width of the semiconductor bar is reduced to about 20 nm.

For the case shown in FIG. 7C, the uniaxial stress ratio becomes greaterthan 50:1 when the bar with is reduced to 20 nm. This added increase instress ratio can be attributed to additional stress relief provided bycutting the underlying oxide 105. In some embodiments, the uniaxialstress ratio for the case shown in FIG. 7C may be greater than 100:1.Other values of uniaxial stress ratio may be obtained for other widthsof the semiconductor bar 390.

FIG. 8 is a graph of transverse-directed stress in a semiconductor bar390 as a function of the width of the semiconductor bar that has beencut from a biaxially-strained layer of material, according to someembodiments. The lower curve 810 in FIG. 8 corresponds to the case wherethe etch through the semiconductor bar stops at the top of the buriedoxide layer 105 (as depicted in FIG. 7A). The upper curve 820corresponds to the case where the etch through the semiconductor barcontinues additionally through the buried oxide layer (as depicted inFIG. 7B). The two curves in FIG. 8 correspond to the values oftransverse stress calculated at the center of the semiconductor bars inthe graphs of FIGS. 7B and 7D. As can be seen in FIG. 8, etching throughthe buried oxide layer can further reduce the transverse stress in thesemiconductor bar. Additionally, the traces also show that the rate ofchange in a reduction of transverse stress increases significantly belowa semiconductor bar width of approximately 300 nm.

FIG. 9 represents experimental results of normalized drive current as afunction of width W* for a semiconductor bar that is cut from abiaxially-strained layer of SiGe material. The drive current is computedas a current per transverse dimensional unit of the semiconductor bar(e.g., amps/micron) at a fixed bias voltage, and has been normalized toa value obtained for the widest bar width of approximately 1.2 μm. Thethickness of the SiGe layer was approximately 6 nm. The graph shows thatas a width of the semiconductor bar is reduced from approximately 1.2 μmto approximately 20 nm, the normalized current through the barincreases. This increase in current is attributed to an increase incarrier mobility as a result of converting biaxial stress in the bar touniaxial stress. As can be seen from the graph of FIG. 9, in someembodiments, an increase in current of more than a 50% may be obtainedby slicing the semiconductor layer to convert biaxial stress to uniaxialstress within the bar.

Changes in current through FD-SOI transistors having sliced channelregions under various slicing conditions are depicted in FIGS. 10A-10B,according to some embodiments. Each graph represents three cases, inwhich the active regions in each of three transistors having differentnominal width values are sliced into 1 to N parts to create nanoscalesemiconductor bars 390. For each simulation, 1 to N slices are trialeddown to a smallest width of about 20 nm. For example, in FIG. 10A, afirst transistor has a nominal channel width of 1.2 μm represented bycurve 1030, a second transistor has a nominal channel width of 0.48 μmrepresented by curve 1020, and a third transistor has a nominal channelwidth of 0.24 μm represented by curve 1010. For each of the three casesin FIG. 10A, a spacing between the nanoscale semiconductor bars 390 is40 nm. For each of the cases in FIG. 10B, a spacing between thenanoscale semiconductor bars 390 is 5 nm. For both FIG. 10A and FIG.10B, values of current are computed per a nominal transverse width ofthe channel, and then normalized to the current value found for theunsliced active area.

For both the cases of FIG. 10A and FIG. 10B, initial slicing of thetransistors' channels results in a net reduction of current through thedevice as the larger active area is replaced by a single slice having anarrower width for which the transverse strain is not appreciablyrelieved, as indicated in FIG. 8. For the case depicted in FIG. 10A, asthe slicing of the channel goes to finer dimensions (less thanapproximately one-half the initial or nominal bar width wherein morethan one slice may be used to replace the larger active area), currentbegins to increase. Although the current increases, it does not returnto a value of the original uncut channel for the case shown in FIG. 10A.At smaller channel widths, each device in FIG. 10A exhibits a reductionin channel current. The reduction and channel current at fine dimensionscan be attributed to the larger space, approximately 40 nm, between thesemiconductor bars 390 for the embodiments shown in FIG. 10A.

For the embodiments represented by FIG. 10B (where the spacing betweenbars is 5 nm), a net current gain can be achieved. As in FIG. 10A,initial slicing of the transistors' channels results in a net reductionof current through the device (due to a low number of slices andpresence of appreciable transverse strain). However, for the embodimentsof FIG. 10B, finer slicing of the transistors' channels results in a netincrease in current that can exceed the nominal current through theuncut channel of each device. The enhanced current is indicated by thedashed box 1050. In some cases, the current can be more than 30% greaterthan the nominal current through the biaxially-strained, uncut channel.

FIG. 11A graphically represents enhancement in carrier mobility of asemiconductor bar that is cut or etched from a biaxially-strainedsemiconductor layer of SiGe having a thickness of 6 nm. Results from twosimulations are shown. In the first implementation, represented by thelower curve 1120, the spacing between the sliced nanoscale semiconductorbars is 10 nm. In the second implementation, represented by the curve1130, the spacing between the sliced semiconductor bars is 5 nm. Areference trace 1110 is also plotted to show mobility enhancement in asingle bar having the same overall width and having a uniaxial strain ofan equivalent value to that found in the cut bars. The reference traceis provided for comparison purposes only, and represents an idealcondition. The results from the two simulations for different spacesbetween the sliced bars indicate that the mobility increases withdecreasing semiconductor bar width to an upper value, and then decreaseswith further decrease in the width of the bar.

FIG. 11B is an expanded view showing the enhanced mobility (Δμ/μ in thevicinity of the upper value for each implementation depicted in FIG.11A. For the implementation in which there is a 10 nm space between eachsemiconducting bar (trace 1120), an upper value of enhanced mobility isfound to occur when the semiconductor bars 390 have a width ofapproximately 70 nm, indicated by the dashed line to the right. For theimplementation in which there is a 5 nm space between the semiconductingbar, an upper value in enhanced mobility is observed for bar widths ofabout 44 nm. In various embodiments, the width of the semiconductor barsis selected to be approximately equivalent to the upper value ofenhanced mobility, for a particular spacing between the semiconductorbars. In some embodiments, the upper value of enhanced mobility is amaximum value of mobility enhancement that can be obtained by slicingthe active areas of the FD-SOI transistors.

Although the examples described above are primarily directed to strainedSiGe semiconductor, other semiconductor combinations may be used inother embodiments. For example, equivalent process steps may beimplemented for biaxially-strained layers of Si, SiC, GaAs, GaN, InP,GaN, InGaAs, InGaN, and other semiconductor materials.

Although the processing steps depicted in FIGS. 5A-5M illustrate someembodiments for forming uniaxially-strained, nanoscale semiconductorbars, in other embodiments, there may be additional, alternative, orfewer steps.

The technology described herein may be embodied as a method, of which atleast one example has been provided. The acts performed as part of themethod may be ordered in any suitable way. Accordingly, embodiments maybe constructed in which acts are performed in an order different thanillustrated, which may include performing some acts simultaneously, eventhough shown as sequential acts in illustrative embodiments.Additionally, a method may include more acts than those illustrated, insome embodiments, and fewer acts than those illustrated in otherembodiments.

Although the drawings depict one or a few transistor structures, it willbe appreciated that a large number of transistors can be fabricated inparallel following the described semiconductor manufacturing processes.A FD-SOI device fabricated according to the present teachings may beformed in an integrated circuit in large numbers and at high densities.The circuits may be used for various low-power applications, includingbut not limited to, circuits for operating smart phones, computers,tablets, PDA's and other consumer electronics. The transistors may beincorporated as part of one or more microprocessors or memory circuitryfor digital or analog signal processing devices. The transistors may beincorporated in logic circuitry, in some implementations. Thetransistors may be used in additional consumer electronic devices suchas televisions, sensors, microcontrollers, field-programmable gatearrays, application specific integrated circuits, analog chips, anddigital signal processing chips.

Having thus described at least one illustrative embodiment of theinvention, various alterations, modifications, and improvements willreadily occur to those skilled in the art. Such alterations,modifications, and improvements are intended to be within the spirit andscope of the invention. Accordingly, the foregoing description is by wayof example only and is not intended as limiting. The invention islimited only as defined in the following claims and the equivalentsthereto.

1. A method comprising: forming a biaxially-strained semiconductor layerdisposed on a substrate having an insulator formed therein; forming anarray of mandrels adjacent to the biaxially-strained semiconductorlayer; coating the mandrels with a conformal spacer layer; removingfirst portions of the conformal spacer layer to expose upper surfaces ofthe mandrels while retaining second portions of the conformal spacerlayer adjacent to sidewalls of the mandrels; covering the mandrels andsecond portions with a first hard mask; patterning the first hard maskto expose upper surfaces of the second portions of the conformal spacerlayer; patterning the conformal spacer layer to form openings betweenthe mandrels and remaining first hard mask; and etching through theopenings to expose strips of the biaxially-strained semiconductor layer.2. The method of claim 1, further comprising oxidizing the exposedstrips to impart uniaxial strain to portions of the semiconductor layer.3. The method of claim 1, further comprising etching through the exposedstrips to form a horizontal array of uniaxially-strained nanoscalesemiconductor bars.
 4. The method of claim 3, wherein etching throughthe exposed strips of the biaxially-strained semiconductor layerconverts biaxial strain in the semiconductor layer to predominantlyuniaxial strain.
 5. The method of claim 4, wherein a uniaxial strainratio of the semiconductor bars is greater than 10:1.
 6. The method ofclaim 4, wherein a uniaxial strain ratio of the semiconductor bars isgreater than 50:1.
 7. The method of claim 3, further comprising etchingthrough exposed portions of the insulator after etching through theexposed strips of the biaxially-strained semiconductor layer.
 8. Themethod of claim 1 further comprising etching through a second hard masklocated between the mandrels and the biaxially-strained semiconductorlayer.
 9. The method of claim 1 wherein the exposed strips of thebiaxially-strained semiconductor layer have a width defined by athickness of the conformal spacer layer that is less than approximately30 nm.
 10. The method of claim 1 wherein the exposed strips of thebiaxially-strained semiconductor layer have a width defined by athickness of the conformal spacer layer that is less than approximately10 nm.
 11. The method of claim 8, further comprising: removing themandrels and the first hard mask; and forming a single contiguous gatestructure over a plurality of the uniaxially-strained nanoscalesemiconductor bars.
 12. The method of claim 11, wherein forming thesingle contiguous gate structure comprises: forming a gate insulatorover at least a portion of the uniaxially-strained nanoscalesemiconductor bars; and forming a gate conductor over the gateinsulator.
 13. The method of claim 12, further comprising forming amerging semiconductor material at source regions of theuniaxially-strained nanoscale semiconductor bars to electrically connectthe source regions.
 14. The method of claim 12, further comprisingepitaxially growing a semiconductor material at drain regions of theuniaxially-strained nanoscale semiconductor bars to electrically connectthe drain regions.
 15. The method of claim 12, further comprisingfilling regions between the uniaxially-strained, nanoscale,semiconductor bars with an insulator.
 16. A method, comprising: forminga plurality of semiconducting bars on a substrate having an insulatorformed therein, the semiconducting bars arranged in a horizontal arrayand spaced apart from one another by a spacing that is less than 30 nm,the semiconducting bars including source regions, drain regions, andchannel regions therebetween; and forming a single and contiguous gateextending over the horizontal array.
 17. The method of claim 16, furthercomprising coupling selected ones of the source regions to one another.18. The method of claim 17 wherein the coupling includes epitaxialgrowth of a source merging material.
 19. The method of claim 16, furthercomprising coupling selected ones of the drain regions to one another.20. The method of claim 19 wherein the coupling includes epitaxialgrowth of a drain merging material.
 21. A method, comprising: forming aplurality of uniaxially strained semiconducting bars on a substratehaving an insulator formed therein, the uniaxially strainedsemiconducting bars arranged in a horizontal array and spaced apart fromone another by a spacing that is less than 30 nm, each of the uniaxiallystrained semiconducting bars including a source region, a drain region,and a channel region extending between the source region and the drainregion; forming a single and contiguous gate extending over theuniaxially strained semiconducting bars; growing a first epitaxial filmover the source regions of the uniaxially strained semiconducting bars;patterning the first epitaxial film to couple selected ones of thesource regions to one another; growing a second epitaxial film over thedrain regions of the uniaxially strained semiconducting bars; andpatterning the second epitaxial film to couple selected ones of thedrain regions to one another;